1. But I thought nothing in life is free?!
Free Energy and ATP
But I thought nothing in life is free?!

2. Spontaneous vs. Nonspontaneous
Spontaneous processes: those that can occur without outside help
example: your room getting messy!
increases stability of a system
Nonspontaneous processes: those that can only occur if energy is added to a system
example: cleaning up your room!
decreases stability of a system

3. Free Energy
Free energy provides a criterion for measuring spontaneity of a system.
Free energy is the portions of a system’s energy that is able to perform work when temperature is uniform throughout the system.

4. Free Energy Examples High Free Energy:
compressed springs
separated charges
These are unstable and tend to move toward a more stable state, one with less free energy.

5. Free Energy Equation Free energy = G Total energy = H Entropy = S
Temperature (Kelvin) = T
G = H – TS

6. Change(∆) in Free Energy
∆ G = G final state - G starting state
Or… ∆ G = ∆ H - T ∆ S
For a system to be spontaneous, the system must either give up energy (decrease in H), give up order (decrease in S), or both.
∆ G must be negative.
The more negative, means the more work can be done.
Nature runs “downhill.”

7. Chemical Reactions HOT COLD
Chemical reactions can be classified based on free energy:
exergonic reaction: proceeds with a net release of free energy (∆G is negative)
endergonic reaction: absorbs free energy from its surroundings (∆G is positive)
HOT
COLD

8. Is this an endergonic or exergonic reaction?!

9. Exergonic Reaction ∆G is negative Example: breakdown of sugar
∆G = -686 kcal/mol
Through this reaction 686 kcal have been made available to do work in the cell.

10. Endergonic Reaction ∆G is positive Endergonic reactions store energy
nonspontaneous
Example:
Cleaning your room!!
Photosynthesis making sugar =
+ 686 kcal

11. Equilibrium A system at equilibrium is at maximum stability.
forward and backward reactions are equal
no change in the concentration of products or reactants
At equilibrium ∆ G = 0 and the system can do no work.
Movements away from equilibrium are nonspontaneous and require the addition of energy from an outside energy source (the surroundings).
Reactions in closed systems eventually reach equilibrium and can do no work.

12. Equilibrium in Cells
A cell that has reached metabolic equilibrium has a ∆ G = 0 and is dead!
Metabolic disequilibrium is one of the defining features of life.
Cells maintain disequilibrium because they are open with a constant flow of material in and out of the cell.
A cell continues to do work throughout its life.

13. Cells have to work?! What powers all this work?
A cell does three main kinds of work:
1. Mechanical work: beating of cilia, contraction of muscle cells, and movement of chromosomes.
2. Transport work: pumping substances across membranes against the direction of spontaneous movement.
Chemical work: driving endergonic reactions such as the synthesis of polymers from monomers.
What powers all this work?

14. ATP! The energy that powers cellular work is ATP!
ATP (adenosine triphosphate) is a type of nucleotide consisting of the nitrogenous base adenine, the sugar ribose, and a chain of three phosphate groups.

15. How does ATP release energy?
The bonds between phosphate groups can be broken by hydrolysis.
Hydrolysis of the end phosphate group forms adenosine diphosphate [ATP -> ADP + Pi] and releases 7.3 kcal of energy per mole of ATP under standard conditions.
∆G is about -13 kcal/mol

16. Why does this release energy?
Bonds are unstable… their hydrolysis yields energy because the products are more stable.
The phosphate bonds are weak because each of the three phosphate groups has a negative charge.
Their repulsion contributes to the instability of this region of the ATP molecule.

17. How is the energy harnessed?
the energy from the hydrolysis of ATP is coupled directly to endergonic processes by transferring the phosphate group to another molecule.
This molecule is phosphorylated.
now more reactive.

18. Where does the ATP come from?
ATP is continually regenerated by adding a phosphate group to ADP.
Energy for renewal comes from catabolic reactions in the cell (breakdown of sugar!).
In a working muscle cell the entire pool of ATP is recycled once each minute, over 10 million ATP consumed and regenerated per second per cell.